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G01F1/00—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through the meter in a continuous flow

G01F1/05—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through the meter in a continuous flow by using mechanical effects

G01F1/10—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through the meter in a continuous flow by using mechanical effects using rotating vanes with axial admission

G01F1/115—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through the meter in a continuous flow by using mechanical effects using rotating vanes with axial admission with magnetic or electromagnetic coupling to the indicating device

Description

This invention relates to flowmeters, and comprises particularly a novel form of device for measuring the rate of flow of either liquids or gases. In the embodiment chosen for illustration, the invention is particularly adapted for use as a fluid flowmeter for aircraft engines.

It is an object of the invention to improve the mounting and operation of the rotors of measuring apparatus of the type employed to measure the rate of flow of fluids.

In this connection, it is also an object of the invention to provide a mounting for the rotors of flowmeters or the like, that will serve both to mount the rotor and eliminate turbulence of fluid flow adjacent thereto.

From this aspect as well as that of registering the rate of fluid flow, it is an object of the present invention to provide a rotor mounting ail'ording highly accurate operation of the mechanism.

In attaining these results, it is an object of the present invention to provide rotor mounting means affording, in conjunction with the operating parts of the mechanism, an instrument which will withstand shock incident to handling and service operations and which at all times will operate with the highest precision and accuracy.

Further objects will be apparent from a reading of the annexed specification and claims, together with an examination of the drawing, in which:

F l is a longitudinal section through a flowmeter;

Fig. 2 is a section on the line 22 of Fig. 1;

Fig. 3 is a section on the line 3-3 of Fig. 1;

Fig. 4 is a wiring diagram for the apparatus; and

Fig. 5 is a wiring diagram of an alternative arrangement.

The flow responsive instrument, per se, comprises a barrel or conduit l0 within which is disposed a helical vane II in the form of a twisted ribbon, any element of the surface of the vane lying at approximately 45 to the fluid path through the conduit. The ends of the vane II are formed as spindles l2, coned at their ends as tained within sleeves l5 into the outer ends of which are inserted plugs l6 each having a streamlined nose.. Axially coextensive withthe sleeves l5, counterbores I! are formed in the barrel, and, as best shown in Fig. 3, a plurality of small cylinders of thin and resilient metal are the sleeves are held central within the barrel. these cylinders being indicated at It. The cylinders l8 seat in arcuate recesses l9 formed in the outer surface of the sleeves i5, so that the latter are held in place. The cylinders II, as well as providing support for the bearing sleeves i5, also comprise guide vanes by which fluid entering and leaving the barrel I0 is held to a straight path past the vane II. The ends of the barrel In are provided with screw threads 20 upon which union nuts 2| may be threaded to clamp pipes 22 to the conduit for fluid ingress and fluid egress.

The barrel I0 is preferably made from nonmagnetic material and is provided with a rigid flange 23 formed at its outer periphery with threads 24, and engaging with the threads 24 is a cover element 25 having a central perforation, embracing the barrel Ill and bearing upon a small flange 26 integral with the barrel. Thus, an annular space is defined between the elements 23 and 25. Within this space substantially semi-circular pole elements 21 are disposed, each having pole pieces 28 and 29 lying close to the outer surface of the barrel l0 so that they are in electro-magnetic relation with a permanent magnet 30 secured within the material of the vane II. This magnet is a bar magnet, and may be made from conventional material, or

30 from some of the more recently developed magnetic materials which have great magnetic stability. Preferably, the magnet 30 is inserted into a cross drilling in the vane ll. so that it is wholly embraced by the material of the vane and oilers no obstruction, of itself, to fluid flow. The pole pieces 21 are provided with windings 3|, and the elements 21 to 3|, inclusive, comprise a small alternating current generator whose output, in either or both frequency and E. M. F;, is

proportional to the rate of fluid flow through the barrel ill; the frequency and E. "M. F. developed by the generator is proportional to the rate Fig. 4 shows one arrangement by which the voltage developed by the generator may readily be measured. The generator, indicated in its entirety as 34, is connected through a plurality of rectiflers 35, 36, 31 and 38 to a direct current voltmeter 39 which may be calibrated in any .suitable manner to indicate rate of fluid flow.

For instance, if the device is used for measuring gasoline flow in an aircraft installation. the voltmeter may be calibrated in gallons per hour or in pounds of fluid per hour. The several rectisprung into place to comprise spokes by which flers 35 to 38 are preferably of the .copper oxide type and may be housed in the instrument as indicated in Figs. 1 and 2. The four rectiners indicated in Fig. 4 provide full wave rectification of the power generated by the generator 14, and the voltage delivered to the voltmeter I! will suffer a certain diminution as a result of the length of connecting wire and the resistance through the rectifiers. However, since it is contemplated that the generator itself have a substantial resistance of the order of 2,000 ohms or more, and that the voltmeter likewise have a substantial resistance, the length of wires used for connecting the generator and voltmeter will have a relatively small effect upon calibration of the instrument.

Fig. 5 shows an alternative arrangement wherein the generator 34 delivers its power output to the primary winding 40 of a saturated core transformer 4|, the secondary 42 of which is split and is connected in the usual manner to a double wave copper oxide rectifier 43 and to a direct current voltmeter 44. In this case, the transformer 4| may be placed adjacent the voltmeter 44, and the length of wires connecting the generator with the transformer is immaterial, for the transformer, being of the saturated core type, is responsive only to frequency. In other words, the voltage output of the transformer is proportional to the frequency input thereto, and accordingly, since the frequency is proportional to the R. P. M. of the vane II, the voltage output from the transformer will likewise be proportional thereto, this voltage being measureable directly upon a D. C. voltmeter.

Certain flowmeter installations are subject to wide variations in temperature which, unless compensation is made, will produce erroneous indications of rate of fluid flow. Accordingly, I incorporate in the flowmeter itself, automatic temperature compensation which may take either one of several forms. In one method of effecting automatic temperature compensation, I utilize a wire in the windings of the generator whose increase in resistance, with changes in temperature, is proportional to the increase in volume of the fluid to be measured. For instance, the volume of gasoline increases approximately 3.4% per unit weight with a 50 F. rise in temperature, which would tend to make the meter register 3.4% too high. Now, if the windings be formed from a metal whose increase in resistance is approximately 3.4% for the same temperature change, the output of the generator will be lessened with increases in temperature in the same proportion as the density of the fluid is decreased, whereby, for any unit of time, and regardless of temperature, the weight of fluid will be accurately measured. Certain alloys of copper and zinc or copper and aluminum may be proportioned so as to obtain the desired 3.4% change in resistance for a 50 F. temperature change when a fluid such as gasoline is to be measured, and adjustments may be made in the composition of the material to adapt it for use with any other fluid having a diflferent coefficient of expansion.

An alternative means of temperature compensation would comprise fabricating the vane H from a bimetallic strip so that, with increase in temperature, and consequent decrease in density of the fluid, the spiral vane would tend to straighten out and would make less turns per unit of volume passing through the flowmeter, but would make the same number of turns per unit of weight passing through the fiowmeter.

ill

Fig. 1, it is preferred that the generator 34 and the rectiiiers to 38 be embedded in a suitable sealing compound, and electrical connections therefrom may be made through a conventional detachable plug organization hown at 46. It might be here mentioned that the design of the generator 34 should be such that small output is obtained-such an instrument which has been constructed and successfully used produces an output of about 5 volts and 1 milliampere under normal rating conditions.

Although the instrument shown in the drawings is designed particularly as a fluid fiowmeter, the same device with suitable changes in size and form is adapted for use as an airspeed indicator or for a log to indicate the speed of water craft.

While I have described my invention in detail in its present preferred embodiment, it will be obvious to those skilled in the art, after understanding my invention, that various changes and modifications may be made therein without departing from the spirit or scope thereof. I aim in the appended claims to cover all such modifications and changes.

I claim as my invention:

1. In a mechanism comprising a hollow support, a bearing carrier therein, and a plurality of annular spoke elements therebetween axially parallel to the bearing carrier, at least one of said elements comprising an annular spring insertible after assembly of the other elements and carrier to retain the carrier in fixed position in the support hollow, said carrier and support having recesses within which said elements engage.

2. In a mechanism, a hollow support comprising an annular wall, a bearing carrier of smaller diameter than the wall annulus having segmental recesses in its periphery, and diametrically deformable spring cylinders having a free diameter greater than the distance between said wall and the bottoms of said recesses, when the carrier is concentric with the wall annulus, inserted between the wall and carrier and engaging said carrier recesses.

3. In a mechanism, a hollow support comprising an annular wall, a cylindrical bearing carrier concentric with and smaller in diameter than the wall annulus, and a plurality of diametrically deformable hollow spring cylinders having a free diameter greater than the difference in radius of said wall and carrier when the latter are concentric, said cylinders being sprung into the space between the wall and carrier in axially parallel relation thereto and contacting the surfaces of Referring again to the instrument shown in said wall and carrier along cylindrical elements thereof.

4. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon rotor carrying means disposed in said conduit coaxially with and extending from said rotor, the combination with the rotor carrying means and the conduit, of means arranged therebetween for holding the rotor carrying means in concentric relation with the conduit and comprising a series of thin annular metallic elements ring-like in cross-section having openings extending therethrough in the direction of the length of the conduit, the series of elements before association thereof with the rotor carrying means and the conduit each having a diameter greater than the distance between said rotor carrying means and conduit when the latter are concentric, said elements being deformed diametrically thereof and' sprung between the rotor carrying means and the conduitintoengagement therewith.

5. In a rotor'mounting: fonmeasuring;. appa ratus of the class wherein the rotor is mountedfor fluid actuation thereof in a conduit upon rotor carrying means disposed in saidconduit coaxially with and. extending from said rotor, the combination with the-rotor carrying means the conduit, of means arranged therebetween for holding the rotor carrying. means in concentric relation with the conduit and comprising a 'series of thin annular metallic elements ring-like in cross-section having openings extending'thereing deformed diametrically thereof and sprung between the rotor carrying means and the con duit into engagement therewith.

6. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon rotor carrying means disposed in said conduit co-axially with and extending from said rotor, the combination with the rotor carrying means and the conduit, of means arranged tberebetween for holding the rotor carrying means in concentric relation with the conduit and comprising a plurality of thin annular metallic elements ringlike in cross-section having openings extending therethrough in the direction of the length of the conduit, one of said means being positioned in recesses formed in the other of said means, the plurality of elements before association thereof with the rotor carrying means and the conduit each having a diameter greater than the distance between said rotor carrying means and conduit when the latter are concentric, said elements being deformed diametrically thereof and sprung between the rotor carrying means and the conduit into engagement therewith.

7. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon rotor carrying means disposed in said conduit co-axially with and extending from said rotor, the combination with the rotor carrying means and the conduit, of means arranged therebetween for holding the rotor carrying means in concentric relation with the conduit and comprising a plurality of thin annular metallic elements ringlike in cross-section having openings extending therethrough in the direction of the length of the conduit, the plurality of elements before association thereof with the rotor carrying means and the conduit each having a diameter greater than the distance between said rotor carrying means and conduit when the latter are concentric, said elements being deformed diametrically thereof and sprung between the rotor carrying means and the conduit into engagement therewith upon the interior wall of the conduit and the walls of recesses formed in the rotor carrying means in spaced relation about the same.

8. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon rotor carrying means disposed in said conduit coaxially with and extending from said rotor, the combination with the rotor carrying means and the conduit, of means arranged therebetween for M81111! the direction efigfihe length of the. conduit, the serieaaobelements, w a: of; cylin- 'drical tubular form and-before thereof with the rotor carrying meansandthm, v

conduit each having a diameter greater than the distance between saidrntqr carryingmeans aridconduit'when the latterare concentric, said-elements being deformeddiametrically thereof and, sprung between the rotor carrying means and the conduit 'intoengagement. therewith upon the interior wall of the conduit-and the walls of recesses formed in the rotorcarrying means inspaced relation about the same.

9. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced, rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with; the conduit and the rotor carrying means, of means forming said vanes and holding the rotor and its carrying means in concentric relation with the conduit, said vane' forming means comprising spaced series of thin annular metallic elements ring-like in cross-section having fluid conducting openings through the I same, the spaced series of elements being sprung diametrically thereof between and engaged with the conduit and the rotor carrying means in positions such that said openings extend through the elements in the direction of the length of said conduit.

10. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with the conduit and the rotor carrying means, of means forming said vanes and holding the rotor and its carrying means in concentric relation with the conduit, said vane forming means comprising spaced series of thin annular metallic elements ring-like in cross-section having fluid conducting openings through the same, the elements being of cylindrical tubular form and sprung diametrically thereof be tween and engaged with the conduit and the rotor carrying means in positions such that said openings extend through the elements in the direction of the length of said conduit.

11. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with the conduit and the rotor carrying means, of means forming said vanes and holding the rotor and its carrying means in concentric relation with the conduit, said vane forming means comprising spaced series of thin annular metallic elements ring-like in cross-section having fluid conducting openings through the same, the spaced series of elements being sprung diametrically thereof between and engaged with the conduit and the rotor carrying means, the diametrically sprung elements bearholding the rotor carrying means in concentrlcrelation with the condintandcomprising-a series oi thin annular metallic elements'rinl elike in cross sectionl aeving g openings extending there- V ing against spaced shouldered interior wall portions of the conduit and being in positions such that said openings extend through the elements in the direction of the length of said conduit and said shouldered interior wall portions prevent accidental displacement of said elements, the rotor carrying means and the rotor longitudinally of the conduit.

12. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with the conduit and the rotor carrying means, of means forming said vanes and holding the rotor and its carrying means in concentric relation with the conduit, said vane forming means comprising spaced pluralities of thin annular metallic elements ring-like in crosssection having fluid conducting openings through the same, the spaced plurallties of elements being sprung diametrically thereof between and engaged with the conduit and the rotor carrying means, the diametrically sprung elements bearing against spaced shouldered interior wall portions of the conduit and against the walls of recesses formed in the rotor carrying means in spaced relation about the same, the elements of the spaced pluralities thereof being in positions such that said openings extend through the elements in the direction of the length of said conduit and said shouldered wall portions and said recesses prevent accidental displacement of said elements, the rotor carrying means and the rotor longitudinally and transversely of said conduit.

13. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with the conduit and the rotor carrying means, of means forming said vanes and holding the rotor and its carrying means in concentric relation with the conduit, said vane forming means comprising spaced series of thin annular metallic elements ring-like in cross-section having fluid conducting openings through the same, the spaced series of elements being of elongated cylindrical tubular form and sprung diametrically thereof between and engaged with the conduit and the rotor carrying means, the diametrically sprung elements bearing against spaced elongated shouldered interior wall portions of the conduit and against the walls of elongated recesses formed in the rotor carrying means in spaced relation about the same, the elements of the spaced series thereof being in positions such that said openings extend through the elements in the direction of the length of said conduit and said shouldered wall portions and said recesses prevent accidental displacement of said elements, the rotor carrying means and the rotor longitudinally and transversely of said conduit.

14. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with the rotor carrying means and outwardly shouldered spaced annular counterbored portions of the conduit formed interiorly thereof to extend around said rotor carrying means in spaced relation therewith, of means forming said vanes and holding the rotor and its carrying means in the conduit concentrically therewith, said vane forming means comprising spaced series of thin annular metallic elements ring-like in cross-section having fluid conducting openings through the same, the spaced series of elements being sprung diametrically thereof between and engaged with the rotor carrying means and the annular counterbored portions of the conduit in positions such that said openings extend in the direction of the length of the conduit and the outwardly disposed shoulders of said counterbored portions prevent accidental displacement of said elements, the rotor carrying means and the rotor longitudinally of the conduit.

15. In a rotor mounting for measuring apparatus of the class wherein the rotor is mounted for fluid actuation thereof in a conduit upon spaced cylindrical rotor carrying means disposed in said conduit co-axially with and extending from opposite ends of said rotor, and fluid straightening vanes are provided in the conduit adjacent the rotor, the combination with the rotor carrying means and outwardly shouldered spaced annular counterbored portions of the conduit formed interiorly thereof to extend around said rotor carrying means in spaced relation therewith, of means forming said vanes and holding the rotor and its carrying means in the conduit concentrically therewith, said vane forming means comprising spaced series of thin annular metallic elements ring-like in cross-section having fluid conducting openings through the same, the elements being of cylindrical tubular form and sprung diametrically thereof between and engaged with the rotor carrying means and the annular counterbored portions of the conduit in positions such that said openings extend in the direction of the length of the conduit and the outwardly disposed shoulders of said counterbored portions prevent accidental displacement of said elements, the rotor carrying means and the rotor longitudinally of the conduit.